distVincentyEllipsoid: 'Vincenty' (ellipsoid) great circle distance
In geosphere: Spherical Trigonometry
View source: R/distVincentyEllipsoid.R
distVincentyEllipsoid R Documentation
'Vincenty' (ellipsoid) great circle distance
Description
The shortest distance between two points (i.e., the 'great-circle-distance' or 'as the crow flies'), according to the 'Vincenty (ellipsoid)' method.
This method uses an ellipsoid and the results are very accurate. The method is computationally more intensive than the other great-circled methods in this package.
Usage
distVincentyEllipsoid(p1, p2, a=6378137, b=6356752.3142, f=1/298.257223563)
Arguments
p1
longitude/latitude of point(s), in degrees 1; can be a vector of two numbers, a matrix of 2 columns (first one is longitude, second is latitude) or a SpatialPoints* object
p2
as above; or missing, in which case the sequential distance between the points in p1 is computed
a
Equatorial axis of ellipsoid
b
Polar axis of ellipsoid
f
Inverse flattening of ellipsoid
Details
The WGS84 ellipsoid is used by default. It is the best available global ellipsoid, but for some areas other ellipsoids could be preferable, or even necessary if you work with a printed map that refers to that ellipsoid. Here are parameters for some commonly used ellipsoids:
ellipsoid a b f
WGS84 6378137 6356752.3142 1/298.257223563
GRS80 6378137 6356752.3141 1/298.257222101
GRS67 6378160 6356774.719 1/298.25
Airy 1830 6377563.396 6356256.909 1/299.3249646
Bessel 1841 6377397.155 6356078.965 1/299.1528434
Clarke 1880 6378249.145 6356514.86955 1/293.465
Clarke 1866 6378206.4 6356583.8 1/294.9786982
International 1924 6378388 6356911.946 1/297
Krasovsky 1940 6378245 6356863 1/298.2997381
a is the 'semi-major axis', and b is the 'semi-minor axis' of the ellipsoid. f is the flattening.
Note that f = (a-b)/a
more info: https://en.wikipedia.org/wiki/Reference_ellipsoid
Value
Distance value in the same units as the ellipsoid (default is meters)
Author(s)
Chris Veness and Robert Hijmans
References
Vincenty, T. 1975. Direct and inverse solutions of geodesics on the ellipsoid with application of nested equations. Survey Review Vol. 23, No. 176, pp88-93.
Available here:
https://www.movable-type.co.uk/scripts/latlong-vincenty.html
https://en.wikipedia.org/wiki/Great_circle_distance
See Also
distGeo, distVincentySphere, distHaversine, distCosine, distMeeus
Examples
distVincentyEllipsoid(c(0,0),c(90,90))
# on a 'Clarke 1880' ellipsoid
distVincentyEllipsoid(c(0,0),c(90,90), a=6378249.145, b=6356514.86955, f=1/293.465)
geosphere documentation built on Nov. 16, 2022, 1:06 a.m.
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View source: R/distVincentyEllipsoid.R
| distVincentyEllipsoid | R Documentation |
'Vincenty' (ellipsoid) great circle distance
Description
The shortest distance between two points (i.e., the 'great-circle-distance' or 'as the crow flies'), according to the 'Vincenty (ellipsoid)' method. This method uses an ellipsoid and the results are very accurate. The method is computationally more intensive than the other great-circled methods in this package.
Usage
distVincentyEllipsoid(p1, p2, a=6378137, b=6356752.3142, f=1/298.257223563)
Arguments
p1 |
longitude/latitude of point(s), in degrees 1; can be a vector of two numbers, a matrix of 2 columns (first one is longitude, second is latitude) or a SpatialPoints* object |
p2 |
as above; or missing, in which case the sequential distance between the points in p1 is computed |
a |
Equatorial axis of ellipsoid |
b |
Polar axis of ellipsoid |
f |
Inverse flattening of ellipsoid |
Details
The WGS84 ellipsoid is used by default. It is the best available global ellipsoid, but for some areas other ellipsoids could be preferable, or even necessary if you work with a printed map that refers to that ellipsoid. Here are parameters for some commonly used ellipsoids:
ellipsoid | a | b | f |
|
WGS84 | 6378137 | 6356752.3142 | 1/298.257223563 |
|
GRS80 | 6378137 | 6356752.3141 | 1/298.257222101 |
|
GRS67 | 6378160 | 6356774.719 | 1/298.25 |
|
Airy 1830 | 6377563.396 | 6356256.909 | 1/299.3249646 |
|
Bessel 1841 | 6377397.155 | 6356078.965 | 1/299.1528434 |
|
Clarke 1880 | 6378249.145 | 6356514.86955 | 1/293.465 |
|
Clarke 1866 | 6378206.4 | 6356583.8 | 1/294.9786982 |
|
International 1924 | 6378388 | 6356911.946 | 1/297 |
|
Krasovsky 1940 | 6378245 | 6356863 | 1/298.2997381 |
|
a is the 'semi-major axis', and b is the 'semi-minor axis' of the ellipsoid. f is the flattening.
Note that f = (a-b)/a
more info: https://en.wikipedia.org/wiki/Reference_ellipsoid
Value
Distance value in the same units as the ellipsoid (default is meters)
Author(s)
Chris Veness and Robert Hijmans
References
Vincenty, T. 1975. Direct and inverse solutions of geodesics on the ellipsoid with application of nested equations. Survey Review Vol. 23, No. 176, pp88-93. Available here:
https://www.movable-type.co.uk/scripts/latlong-vincenty.html
https://en.wikipedia.org/wiki/Great_circle_distance
See Also
distGeo, distVincentySphere, distHaversine, distCosine, distMeeus
Examples
distVincentyEllipsoid(c(0,0),c(90,90)) # on a 'Clarke 1880' ellipsoid distVincentyEllipsoid(c(0,0),c(90,90), a=6378249.145, b=6356514.86955, f=1/293.465)
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